BATTERY GRID
A battery grid is provided having a frame that includes a top element, a bottom element, a first side element, and a second side element. A current collection lug is coupled to the top element. The battery grid includes a plurality of wires provided within the frame defining a plurality of open areas. The plurality of wires includes a plurality of linear vertical wire members which extend from the top element toward the bottom element, first side element, or second side element. At least one of the linear vertical wire members includes a discontinuity terminating the linear vertical-wire member before reaching the bottom element, first side element, or second side element, the discontinuity being defined by parallel horizontal wire members defining an open space.
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This application claims priority as a divisional application of U.S. application Ser. No. 13/097,643, filed Apr. 29, 2011, which is a continuation application of U.S. application Ser. No. 12/823,803, filed Jun. 25, 2010, now U.S. Pat. No. 7,955,737, which is a continuation application of U.S. application Ser. No. 11/984,666, filed Nov. 20, 2007, now U.S. Pat. No. 7,767,347, which is a national stage application of international Application No. PCT/US2006/019686, which has an international filing date of May 22, 2006, which claims the benefit of U.S. Provisional Patent Application No. 60/683,608, filed May 23, 2005, the entire content of which is hereby incorporated by reference herein.
BACKGROUNDThe present inventions relate to grids for use in batteries (e.g., lead-acid batteries such as batteries for vehicle starting, lighting, and ignition applications; marine batteries; commercial batteries; industrial batteries; batteries for use with hybrid-electric vehicles; etc.). More specifically, the present inventions relate to grids that have a configuration which resists shorting of a battery cell due to growth of the grids.
Lead-acid batteries conventionally include a number of cells in which energy is stored. For example, a 12 volt battery may include six cells, each of which provides 2 volts. Each of the cells includes one or more positive electrodes or plates and one or more negative electrodes or plates. An electrolyte (e.g., acid such as dilute sulfuric acid) is also provided in the cells to facilitate chemical reactions which take place in the cells during charging and discharging of the battery.
The positive and negative electrodes each comprise a grid made from lead or a lead alloy (e.g., a lead-calcium alloy) on which an active material in the form of a paste is provided. Such grids include a plurality of wires coupled to a plurality of nodes (e.g., a battery grid may include a frame comprising four sides with a lug or current collector extending from one of the sides and a network of wires or grid elements interconnected with a plurality of nodes).
The positive and negative electrodes are arranged in each of the cells in alternating fashion and are separated from adjacent plates by a separator (e.g., a microporous polymeric separator). For example, the negative electrodes may be contained within a separator envelope to electrically isolate them from adjacent positive electrodes. In this manner, the positive and negative electrodes are prevented from coming into direct contact with each other, which would cause a short in the cell.
Over an extended period of use, the grids will corrode, which in turn will cause the grids to grow. By way of illustration,
Growth of positive electrode 10 is illustrated by dashed lines 30 and 32. When installed in a battery container, the grids are generally constrained on their sides and bottom by walls of the battery container. Accordingly, growth of the grids generally occurs along the top surface of the grids. In certain situations, such unconstrained growth in the positive vertical direction may cause a short of the cell. For example, as shown in
While it is known to provide grids for use in batteries, such known grid configurations do not provide certain advantageous features and/or combinations of features.
SUMMARYAn embodiment of the present invention relates to a battery grid that includes a frame that includes a top element, a bottom element, a first side element, and a second side element. The battery grid also includes a plurality of wires provided within the frame and defining a plurality of open areas and a current collection lug extending from the top element in a first direction. The battery grid further includes at least one feature provided in the battery arid that is configured to reduce the amount of growth of the battery grid in the first direction due to corrosion of the battery grid during the life of the battery grid.
Referring to
A series of radially extending vertical grid wire elements 126 form part of the grid 100. The vertical wire elements 126 are connected to the top frame element 112 and at least one of the bottom frame element 118, the first side frame element 114, and the second side frame element 116. The vertical wire elements 126 become closer together when moving from the bottom element 118 towards the top element 112 and get farther apart when moving towards the left element 114 or the right element 116.
The grid 100 also includes a plurality of horizontal or cross wire elements 130. Individual sections of the vertical wire elements 126 and the horizontal wire elements 130 ends which are joined at a plurality of nodes 144 that define the open areas 120 that support the electrochemically active paste for conduction.
As shown in
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It should be noted that while the above-described modifications to the grid have been discussed individually, any one or more of such modifications may be utilized in a single grid. For example, both a “weak link” (as shown, e.g., in
In operation of a battery using a grid such as that described herein, corrosion of the battery grid material (lead or a lead alloy) will cause growth of the battery grid. Because the grid is constrained at its bottom and sides by the walls of the battery container, growth is directed in the vertical direction toward the top of the grid. By introducing modifications to the grid which are intended to shunt or redirect the growth of the grid, the life of the battery may be extended. For example, by introducing weak points in the grid that are intended to break once a threshold amount of stress is reached, growth may be interrupted or redirected at such points to reduce the growth of the grid in the vertical direction. Any of a variety of modifications may be made to the grid in order to manage the growth of the grid and extend the life of the battery by reducing the occurrence of shorts which result from portions of the grid contacting features electrically coupled to features in the battery having an opposite polarity.
Those reviewing this disclosure will appreciate that various advantages may be obtained using the grid designs described herein. For example, according to an exemplary embodiment, the battery grid provides desired performance characteristics while resists shorting due to grid growth. The battery grid includes features which are intended to act to retard, restrain or restrict growth of the grid due to corrosion. According to an exemplary embodiment, the battery grid includes one or more modifications that are intended to absorb or redirect stresses that may result from growth of the grid (e.g., due to corrosion of the grid). It is intended that such grid designs provide the battery grid, and hence the battery in which it is provided, with an enhanced useful life as compared to conventional battery grids.
It is important to note that the construction and arrangement of the battery grid as shown in the various embodiments is illustrative only. Although only a few embodiments of the present inventions have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters, mounting arrangements, use of materials, orientations, etc.) without materially departing front the novel teachings and advantages of the subject matter recited in the claims. Accordingly, all such modifications are intended to be included within the scope of the present invention as defined in the appended claims. Other substitutions, modifications, changes and omissions may be made in the design, operating conditions and arrangement of the preferred and other exemplary embodiments without departing from the scope of the present inventions.
Claims
1. A battery grid comprising:
- a frame including a top element, a bottom element, a first side element, and a second side element;
- a current collection lug coupled to the top element;
- a plurality of wires elements provided within the frame and defining a plurality of open spaces, including a plurality of linear vertical wire members extending from the top element toward the bottom element, first side element, or second side element, at least one of the linear vertical wire members includes a discontinuity terminating the linear vertical wire member before reaching the bottom element, first side element, or second side element, the discontinuity is defined by parallel horizontal wire members defining an open space.
2. The battery grid of claim 1, further comprising a second linear vertical wire member extending from the bottom element toward the top element, first side element, or second side element, the second linear vertical wire member includes a second discontinuity terminating the second linear vertical wire member before reaching the top element, first side element, or second side element, the second discontinuity is defined by parallel horizontal wire members defining a second open space.
3. The battery grid of claim 1, wherein the battery grid comprises at least one rounded corner between the top element and one of the first or second side elements.
4. The battery grid of claim 1, wherein the top element meets the first or second side elements at an angle such that at least a portion of the top element is not perpendicular to at least one of the first and second side elements.
5. The battery grid of claim 1, wherein the parallel horizontal wire members defining the discontinuity contiguously extend from the first side element to the second side element.
6. The battery grid of claim 2, wherein the parallel horizontal wire members defining the discontinuity terminating the first linear vertical wire member contiguously extend from the first side element to the second side element, and the parallel horizontal wire members defining the second discontinuity terminating the second linear vertical wire member contiguously extend from the first side element to the second side element.
7. The battery grid of claim 1, wherein the plurality of linear vertical wire members further comprise:
- a first wire member extending from the top element toward the bottom element, the first wire member includes a discontinuity terminating the first wire member before reaching the bottom element, the discontinuity is defined by parallel horizontal wire members defining an open space;
- a second wire member extending from the top element toward the first side element, the second wire member including a discontinuity terminating the second wire member before reaching the first side element, the discontinuity is defined by parallel horizontal wire members defining an open space; and
- a third wire member extending from the top element toward the second side element, the third wire member including a discontinuity terminating the third wire member before reaching the second side element, the discontinuity is defined by parallel horizontal wire members defining an open space.
8. A battery grid comprising:
- a frame including a top element, a bottom element, a first side element, and a second side element;
- a current collection lug coupled to the top element;
- a plurality of wires elements provided within the frame and defining a plurality of open spaces, including a plurality of linear wire members radially extending from the top element toward the bottom element, first side element, or second side element, the plurality of linear wire members includes a first wire member extending from the top element toward the bottom element, the first wire member includes a discontinuity terminating the first wire member before reaching the bottom element, the discontinuity being defined by parallel wire members defining an open space, a second wire member extending from the top element toward the first side element, the second wire member includes a discontinuity terminating the second wire member before reaching the first side element, the discontinuity being defined by parallel wire members defining an open space, and a third wire member extending from the top element toward the second side element, the third wire member includes a discontinuity terminating the third wire member before reaching the second side element, the discontinuity being defined by parallel wire members defining an open space.
9. The battery grid of claim 8, wherein the parallel wire members defining the discontinuity terminating the first wire member includes a fourth wire member which originates from the first side element or second side element, and a fifth wire member which originates from the first side element or second side element.
10. The battery grid of claim 9, wherein the parallel wire members defining the discontinuity terminating the second wire member includes a sixth wire member which originates from the first side element or second side element, and a seventh wire member which originates from the first side element or second side element.
11. The battery grid of claim 10, wherein the parallel wire members defining the discontinuity terminating the third wire member includes a eighth wire member which originates from the first side element or second side element, and a ninth wire member which originates from the first side element or second side element.
12. The battery grid of claim 8, wherein the parallel wire members defining each discontinuity contiguously extend from the first side element to the second side element.
13. battery grid of claim 8, further comprising a fourth wire member extending from the bottom element toward the top element, the fourth wire member includes a discontinuity terminating the fourth wire member before reaching the top element, the second discontinuity being defined by parallel horizontal wire members defining an open space.
14. The battery grid of claim 8, wherein the battery grid comprises at least one rounded corner between the top element and one of the first or second side elements.
15. The battery grid of claim 8, wherein the top element meets the first or second side elements at an angle such that at least a portion of the top element is greater than ninety degrees to at least one of the first and second side elements.
16. A battery grid comprising:
- a frame including a top element, a bottom element, a first side element, and a second side element;
- a current collector coupled to the top element;
- a plurality of wires elements provided within the frame and defining a plurality of open spaces, including a plurality of linear wire members which radially extend outward from the top element, and a plurality of horizontal wire elements which originate from the first side element or the second side element, the plurality of linear wire members include a first wire element which extends from the top element toward the bottom element, the first wire element includes a discontinuity terminating the first wire element before reaching the bottom element, the discontinuity being defined by parallel horizontal wire elements defining an open space.
17. The battery grid of claim 16, wherein the plurality of linear wire members include a second wire element which extends from the bottom element toward the top element, the second wire element includes a discontinuity terminating the second wire element before reaching the top element, the discontinuity being defined by parallel horizontal wire elements defining an open space.
18. The battery grid of claim 17, wherein the plurality of linear wire members include a third wire element and a fourth wire element, the third wire element extends from the top element toward the first side element, the third wire element includes a discontinuity terminating the third wire element before reaching the first side element, the discontinuity being defined by parallel horizontal wire elements defining an open space, and the fourth wire element extends from the top element toward the second side element, the fourth wire element includes a discontinuity terminating the fourth wire element before reaching the second side element, the discontinuity being defined by parallel horizontal wire elements defining an open space.
19. The battery grid of claim 16, wherein the plurality of linear wire members include a third wire element which extends from the top element toward the first side element, the third wire element includes a discontinuity terminating the third wire element before reaching the first side element, the discontinuity being defined by parallel horizontal wire elements defining an open space.
20. The battery grid of claim 16, wherein the plurality of linear wire members include a fourth wire element which extends from the top element toward the second side element, the fourth wire element includes a discontinuity terminating the fourth wire element before reaching the second side element, the discontinuity being defined by parallel horizontal wire elements defining an open space.
Type: Application
Filed: Apr 26, 2012
Publication Date: Aug 23, 2012
Patent Grant number: 8399135
Applicant: Johnson Controls Technology Company (Holland, MI)
Inventors: Wen-Hong Kao (Brown Deer, WI), Shu Jen F. Fao (Brown Deer, WI), Glenn W. Anderson (Hartford, WI), M. Eric Taylor (Shorewood, WI), Kenneth A. Adams (Germantown, WI), Edward N. Mrotek (Grafton, WI), Jeffrey P. Zagrodnik (Hales Corners, WI)
Application Number: 13/457,242
International Classification: H01M 4/72 (20060101);